America's Cup Sailing: Effect of Standing Arm-Cranking (“Grinding”)

America's Cup Sailing: Effect of Standing Arm-Cranking (“Grinding”)

sports Article America’s Cup Sailing: Effect of Standing Arm-Cranking (“Grinding”) Direction on Muscle Activity, Kinematics, and Torque Application Simon N. Pearson 1,2,*, Patria A. Hume 1, John Cronin 1 and David Slyfield 1,3 1 Sports Performance Research Institute New Zealand (SPRINZ), School of Sport and Recreation, Faculty of Health and Environmental Science, Auckland University of Technology, Private Bag 92006, Auckland 1020, New Zealand; [email protected] (P.A.H.); [email protected] (J.C.); david.slyfi[email protected] (D.S.) 2 Queensland Academy of Sport, QLD Sport & Athletics Centre, Kessels Rd, Nathan QLD 4111, Australia 3 High Performance Sport New Zealand, PO Box 302 563, North Shore 0751, New Zealand * Correspondence: [email protected]; Tel.: +61-497-548609 Academic Editor: Eling Douwe de Bruin Received: 2 February 2016; Accepted: 8 June 2016; Published: 27 June 2016 Abstract: Grinding is a key physical element in America’s Cup sailing. This study aimed to describe kinematics and muscle activation patterns in relation to torque applied in forward and backward grinding. Ten male America’s Cup sailors (33.6 ˘ 5.7 years, 97.9 ˘ 13.4 kg, 186.6 ˘ 7.4 cm) completed forward and backward grinding on a customised grinding ergometer. In forward grinding peak torque (77 Nm) occurred at 95˝ (0˝ = crank vertically up) on the downward section of the rotation at the end of shoulder flexion and elbow extension. Backward grinding torque peaked at 35˝ (69 Nm) following the pull action (shoulder extension, elbow flexion) across the top of the rotation. During forward grinding, relatively high levels of torque (>50 Nm) were maintained through the majority (72%) of the cycle, compared to 47% for backward grinding, with sections of low torque corresponding with low numbers of active muscles. Variation in torque was negatively associated with forward grinding performance (r = ´0.60; 90% CI ´0.88 to ´0.02), but positively associated with backward performance (r = 0.48; CI = ´0.15 to 0.83). Magnitude and distribution of torque generation differed according to grinding direction and presents an argument for divergent training methods to improve forward and backward grinding performance. Keywords: yachting; biomechanics; movement analysis; performance 1. Introduction The America’s Cup is generally regarded as the most prestigious competition in sailing and is the oldest active trophy in international sport, dating back to 1851 [1]. On-water performance in America’s Cup competition is determined by numerous factors including tactics, crew work and yacht design, however, in terms of physical human performance during racing, grinding is considered to be the primary physical activity [2]. Grinding is a cyclic upper body task requiring the manual arm cranking of winches which control the movement of the mast and sails, making it a crucial component of manoeuvres such as tacking (turning on an upwind leg) and gybing (turning on a downwind) [3]. Grinding is performed in a standing position and the set-up of the winch system means that sailors are required to perform grinding in both a forward direction—pushing away from their body at the top of the rotation; and backward—pulling towards their body at the top of the rotation [2]. In race analysis of the 32nd America’s Cup and associated Louis Vuitton Challenger series, Neville, Calefato et al. [4] reported that an average of 20 tacks (5.5 ˘ 0.5 s in duration) and 8 gybes (11.2 ˘ 1.4 s) were performed during a Sports 2016, 4, 37; doi:10.3390/sports4030037 www.mdpi.com/journal/sports Sports 2016, 4, 37 2 of 12 race. These values were lower than previously reported figures of 30 tacks and 15 gybes per race [5]. However, it was calculated that when combined with mark roundings and the more frequent but less demanding grinding activity of sail trimming, a sailor whose principle role was grinding could expect a work to rest ratio of ~1:6 over an average 82 min race, and up to 1:3 in close racing. More accomplished crews (top four of the 11 challengers) completed manoeuvres in significantly shorter time than less accomplished crews [4], a finding that highlights the important relationship between grinding capability and overall race performance. In addition to the performance aspects, grinders have been identified in a number of epidemiological studies as having the highest rate of injury amongst America’s Cup crew members [6–10]. Although these studies reported sometimes conflicting findings (possibly due to different methodologies), soft tissue injuries to the upper limb made up a large proportion of the preventable (non-accident/impact) injuries suffered by grinders, with the grinding activity itself directly attributed to 30% of injuries in this group [11]. A review of sailing injuries by Neville and Folland [10] suggested that poor technique and strength deficiencies may be risk factors when looking at the grinding task, and as such a better understanding of the muscles, movements, and loading patterns utilised may provide useful information for the preventative conditioning of sailors who perform grinding as part of their on-board role. In recent years there has been an increasing body of research focussed on America’s Cup sailing from sport science and medicine perspective. With regards to the grinding activity in particular, studies examining the physiological [2,5] and strength and power [12] factors associated with performance, along with descriptions of the physical characteristics [4,13], nutritional requirements [14], and competition demands [4,15] have all been published. From a biomechanical perspective, an examination of grinding pedestal (crank-axle) height and crank length reported ground reaction force and kinematic data for forward grinding [16]. Results of this study indicated that while the standard crank length of America’s Cup yachts (250 mm) was near optimal for peak power generation, peak power was significantly greater for forward grinding at higher crank-axle heights (950–1150 mm) than was typically in use (850 mm). While this appears somewhat contradictory to results from seated arm-cranking which concluded that shoulder height relative to the crank axis has no influence on performance [17], Neville et al. identified substantial contribution of the legs to the standing arm cranking movement whereby restricting movement at the knees and ankles (achieved by joint splinting) reduced peak unilateral vertical ground reaction forces (indicating reduced lateral body mass transfer) and significantly increased the physiological strain [18]. Additional factors associated with improved power output through increased pedestal height were a more extended hip position (reduced forward trunk lean), and increased resultant ground reaction force, while it was noted that further examination of upper body function is required [16]. Away from the specific grinding or standing arm-cranking movement there have been a number of other papers on the kinematically similar seated arm cranking exercise, which is often used in rehabilitation and for wheelchair users [19]. Arm cranking papers have reported that hand-grip/forearm orientation affects muscle activation patterns [20], and that backward arm cranking is less proficient than forward, based on reduced kinematic variability at the elbow [21]. Possibly of most relevance, Bressel [19], in a comparison of forward and reverse (backward) seated arm cranking, observed little difference in either upper limb kinematics or oxygen consumption, but found that backward arm cranking required significantly greater activity of the biceps brachii, deltoid, and infraspinatus muscles. While there may be some cross-over from the findings of this body of research, the differences in body position and posture due to the standing position adopted during America’s Cup grinding mean that there is justification in examining the mechanics of this activity in its own right. Concomitantly, of the current research examining the standing arm-cranking movement, so far none have examined both the forward and backward movements. The purpose of this study was therefore to describe the kinetic, kinematic, and muscular activation characteristics of the forward and backward grinding Sports 2016, 4, 37 3 of 12 Sports 2016, 4, 37 3 of 12 movements in America’s Cup sailing. It was hypothesised that the biomechanical requirements of requirements of the two movements would be substantially different, therefore necessitating the two movements would be substantially different, therefore necessitating different approaches different approaches to training. to training. 22.. Materials Materials and and Methods Methods 2.1.2.1. Participants Participants TenTen male America’s America’s Cup Cup sailors sailors (33.6 (33.6 ±˘ 5.75.7 years, years, 97.9 97.9 ± 13.4˘ 13.4 kg, kg,186.6 186.6 ± 7.4˘ cm)7.4 cm)participated participated in this in studythis study by completing by completing the g therinding grinding protocol. protocol. While While the sailors the sailors varied varied in their in their primary primary role rolewithin within the team,the team, all performed all performed grinding grinding regularly regularly as aspart part of oftheir their on on-board-board role. role. As As maximal maximal strength strength has previously been shown to be be a a key key predictor predictor of of grinding grinding performance, performance, one one-repetition-repetition m maximumaximum (1 (1 RM) RM) scoresscores for for the the concentric only bench press (121.7(121.7 ˘± 2626.1.1 kg) kg) and bench pull

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